KR20200071684A - Fluid Sensor Assembly - Google Patents

Abstract

The present invention relates to a fluid sensor assembly (100) for detecting a fluid (102) contained in a fluid tank (104) of a vehicle (106), which comprises a housing unit (110) having a base plate (120), a sample suction line (122) and a sample return line (124). Also, the fluid sensor assembly of the present invention comprises a header assembly (102) having a header housing (134) separately connected to the housing unit. The header housing is located outside the fluid tank of the vehicle. The header assembly has a sample tank (152) in fluid communication with the sample suction line and the sample return line. In addition, the sample tank receives the fluid from the fluid tank, and a fluid quality sensor (154) senses the quality characteristics of the fluid in the sample tank for quality sampling of the fluid at a location separated from the inside of the fluid tank.

Description

Fluid sensor assembly

Objects within this specification generally relate to fluid sensor assemblies.

In some applications, for example in the engine's fuel supply system or the SCR (selective catalytic reduction) device's DEF (diesel exhaust fluid) delivery system, the fluid level needs to be maintained above a certain level, impurity mixed fluid or dilution Fluid quality problems, such as impaired fluids, need to be detected to prevent degradation of system performance and damage to the system. In these applications, fluid level sensors and fluid quality sensors are used to measure fluid levels and monitor fluid quality. For example, the fluid level sensor is a reed switch sensor in various systems, and the fluid quality sensor includes an ultrasonic sensor. The fluid level sensor and fluid quality sensor are typically maintained by a fluid sensor housing in the fluid tank. Monitoring fluid quality within a fluid tank is difficult and can lead to inaccurate quality measurements. Additionally, fluid sensors are integrated into a common sensor unit. When repairing or replacing, it is necessary to remove the sensor unit and replace the entire sensing unit. The problem to be solved is to provide a robust and cost effective fluid sensor assembly.

The above problem is solved by a fluid sensor assembly provided for sensing the fluid contained in the fluid tank of a vehicle comprising a housing unit having a base plate configured to be connected to the fluid tank. The housing unit includes a sample suction line and a sample return line configured to be in fluid communication with a fluid in the fluid tank. The fluid sensor assembly includes a header assembly having a header housing detachably connected to the housing unit. The header housing is configured to be located outside the vehicle's fluid tank. The header assembly has a sample tank in fluid communication with the sample suction line and sample return line. The sample tank is configured to receive fluid from the fluid tank. The header assembly includes a fluid quality sensor that senses the quality characteristics of the fluid in the sample tank for sampling the fluid quality at a location away from the interior of the fluid tank.

The invention will now be described by way of example with reference to the accompanying drawings.

1 is a schematic diagram of a fluid sensor assembly according to an exemplary embodiment.
2 is a schematic view of a header assembly of a fluid sensor assembly according to an exemplary embodiment.
3 is an exploded view of a fluid sensor assembly according to an exemplary embodiment.
4 is an exploded view of a fluid sensor assembly according to an exemplary embodiment.

1 is a schematic diagram of a fluid sensor assembly 100 for sensing fluid 102 contained within a fluid tank 104 of a vehicle 106. The vehicle 106 may be an automobile and agricultural vehicle, an aircraft, or a marine vessel. The fluid sensor assembly 100 can sense one or more fluid properties of the fluid 102. For example, the fluid sensor assembly 100 can sense the concentration of one or more substances in the fluid 102. The fluid sensor assembly 100 can detect contamination of the fluid 102. The fluid sensor assembly 100 can sense other fluid properties such as temperature, viscosity, density, and the like. The fluid 102 can be fuel, oil, hydraulic fluid, transmission fluid, or other types of fluid. In various embodiments, the fluid 102 is a diesel exhaust fluid (DEF), and the fluid sensor assembly 100 is a DEF quality sensor. The DEF quality sensor can detect the quality of urea or other reducing agents in the DEF fluid.

In an exemplary embodiment, the fluid sensor assembly 100 is connected to the vehicle system 108 of the vehicle 106. For example, the fluid sensor assembly 100 can be electrically connected to the vehicle system 108 to deliver data related to the fluid quality of the fluid 102 to the vehicle system 108. The fluid sensor assembly 100 can be electrically connected to the vehicle system 108 to supply power to one or more components of the fluid sensor assembly 100. The fluid sensor assembly 100 can be connected to other types of vehicle systems, such as the coolant system of the vehicle 106, to heat the fluid 102 in the fluid tank 104.

In an exemplary embodiment, the fluid sensor assembly 100 includes a housing unit 110, a header assembly 112, a fluid level sensor assembly 114 and a temperature control device 116. The housing unit 110 includes a base plate 120 configured to be connected to the fluid tank 104. In the exemplary embodiment, the header assembly 112 is detachably connected to the base plate 120 of the housing unit 110. For example, the header assembly 112 can be removable and replaceable relative to the housing unit 110. In an exemplary embodiment, the fluid level sensor assembly 114 is detachably connected to the base plate 120 of the housing unit 110. For example, the fluid level sensor assembly 114 can be removable and replaceable relative to the housing unit 110. In the exemplary embodiment, the fluid level sensor assembly 114 is detachably connected to the header assembly 112. For example, the fluid level sensor assembly 114 can be removable and replaceable relative to the header assembly 112. In the exemplary embodiment, the temperature control device 116 is detachably connected to the base plate 120 of the housing unit 110. For example, the temperature control device 116 can be removable and replaceable relative to the housing unit 110. In the exemplary embodiment, the temperature control device 116 is detachably connected to the header assembly 112. For example, the temperature control device 116 can be removable and replaceable for the header assembly 112.

In an exemplary embodiment, a portion of the fluid sensor assembly 100 is located inside the fluid tank 104 in contact with the fluid 102. For example, a portion of the housing unit 110 and/or a portion of the fluid level sensor assembly 114 and/or a portion of the temperature control device 116 may extend into the fluid tank 104 in contact with the fluid 102. Can be. In an exemplary embodiment, a portion of the fluid sensor assembly 100 is located outside the fluid tank 104 and is spaced apart from the fluid 102. For example, the header assembly 112 can be located outside the fluid tank 104. Optionally, the header assembly 112 may be removable from the housing unit 110 without removing the housing unit 110 from the fluid tank 104.

In the exemplary embodiment, the housing unit 110 includes a sample suction line 122 and a sample return line 124 configured to be in fluid communication with the fluid 102 in the fluid tank 104. Optionally, the sample suction line 122 and the sample return line 124 form a closed sample loop for circulating the sample of fluid 102 through the fluid sensor assembly 100. The sample of fluid is returned to the fluid tank 104 after sampling. The fluid sensor assembly 100 is separate from the main suction line used to remove the fluid 102 from the fluid tank 104, for example, for consumption of the fluid 102 during operation of the vehicle 106. The fluid sensor assembly 100 samples the fluid 102 from the fluid tank 104 rather than sampling the fluid in the main suction line from the fluid tank 104. In an exemplary embodiment, a closed sample loop flows through header assembly 112. For example, the housing unit 110 includes a suction line fitting 126 and a return line fitting 128 in flow communication with the sample suction line 122 and the sample return line 124, respectively. The header assembly 112 includes a corresponding suction line fitting 130 and a corresponding return line fitting 132 configured to be connected to the suction line fitting 126 and return line fitting 128 of the housing unit 110. Fittings 126, 128, 130, and 132 are removable to allow header assembly 112 to be separated from housing unit 110. Fittings 126, 128, 130, 132 may be sealed at each interface to allow connection and disconnection without loss or leakage of fluid 102 within the closed sample loop. Fittings 126 and 128 may be male or female fittings, and fittings 130 and 132 may be male or female fittings. In the illustrated embodiment, suction lines 122 and 124 are connected to base plate 120 and extend into the interior of fluid tank 104, and fittings 126 and 128 are provided to interface with header assembly 112. It is connected to the base plate 120 from the outside of the base plate 120. The fluid 102 moves between the interior of the fluid tank 104 and the exterior of the fluid tank 104 through the housing unit 110. For example, fluid 102 can be sampled in a header assembly 112 outside fluid tank 104 before being circulated back into fluid tank 104 through sample return line 124.

In an exemplary embodiment, the header assembly 112 includes a header housing 134 configured to connect to the base plate 120 of the housing unit 110. In various embodiments, the header housing 134 may be directly connected to the base plate 120. In another alternative embodiment, the header housing 134 can be spaced from the base plate 120 at a remote location and by one or more fluid lines to circulate fluid between the housing unit 110 and the header assembly 112. It may be connected to the housing unit 110.

The header assembly 112 includes a vehicle connector 136 to interface with the vehicle system 108. For example, the electrical connector 138 of the vehicle system 108 is connected to the vehicle connector 136. Electrical signals may be transmitted between the vehicle system 108 and the header assembly 112 via the vehicle connector 136 and the electrical connector 138. For example, data related to fluid quality characteristics measured by fluid sensor assembly 100 can be transmitted to vehicle system 108. Power may be supplied to the header assembly 112 through the electrical connector 138 and the vehicle connector 136.

In an exemplary embodiment, header assembly 112 includes sensor connector 140 configured to be electrically connected to fluid level sensor assembly 114. The fluid level sensor assembly 114 is used to determine the fluid level of the fluid 102 and fluid tank 104. Signals from the fluid level sensor assembly 114 can be transmitted to the header assembly 112 through the sensor connector 140. In an exemplary embodiment, the fluid level sensor assembly 114 includes a reed switch 142 used to sense the fluid level of the fluid 102 and fluid tank 104. The fluid level sensor assembly 114 can include multiple reed switches. In various embodiments, the fluid level sensor can include a float 144 in the fluid tank 104, which is on the float tube 146, the float tube placing the float 144 within the fluid tank 104. . Float 144 floats on top of fluid 102. When the float 144 reaches the reed switch 142, the fluid level sensor assembly 114 can transmit a signal regarding the low fluid level in the fluid tank 104. For example, the reed switch 142 may be connected to a reed switch circuit board 148 electrically connected to the sensor connector 140. Other types of level sensors can be used in alternative embodiments for determining the fluid level in the fluid tank 104. In alternative embodiments, other types of fluid level sensors may be used, such as magnetoresistive units, ultrasonic sensors, and the like.

In the exemplary embodiment, the temperature control device 116 is connected to the base plate 120 of the housing unit 110. Temperature control device 116 extends into fluid tank 104 and may be in thermal contact with fluid 102. The temperature control device 116 can be operated to affect the temperature of the fluid 102 and the fluid tank 104. In the exemplary embodiment, temperature control device 116 includes a heating element for heating fluid 102. For example, the heating element can be an electric heating element powered through the header assembly 112. In an exemplary embodiment, the temperature control device 116 includes a cooling element for cooling the fluid 102. For example, the cooling element can be a refrigerant line that circulates refrigerant through fluid tank 104 to cool fluid 104. The refrigerant line can be connected to the cooling system of the vehicle 106 through, for example, one or more fittings on the base plate 120 of the header assembly 112 and/or the housing unit 110.

In an exemplary embodiment, the fluid sensor assembly 100 is modularly designed to allow repair and/or replacement of one or more elements of the fluid sensor assembly 100 without the need to replace other elements of the fluid sensor assembly 100. do. For example, the header assembly 112 can be removed and replaced with the upgraded header assembly 112 without replacing the housing unit 110 and/or fluid level sensor assembly 114 and/or temperature control device 116. Can be. Independent elements can be manufactured separately. The elements can be produced, tested and calibrated separately from each other and can be integrated with each other. The elements of the fluid sensor assembly 100 are field repairable and/or field replaceable. In an exemplary embodiment, the fluid sensor assembly 100 allows fluid sampling and testing at a location away from the fluid tank 104, such as in a header assembly 112 outside the fluid tank 104. For more accurate testing, the environmental conditions of the fluid during the test can be controlled more repeatedly and consistently. For example, sample testing can be performed away from poor operating environments. For example, the temperature and pressure of the fluid being sampled can be better controlled in the header assembly 112 outside the fluid tank 104 as opposed to in situ in the fluid tank 104.

2 is a schematic diagram of a header assembly 112 of a fluid sensor assembly 100 according to an exemplary embodiment. The header assembly 112 includes components within the header housing 134. In an exemplary embodiment, header housing 134 may be sealed to provide a sealed environment for components and for fluid testing. Suction line fitting 130 and return line fitting 132 extend from header housing 134 to interface with housing unit 110 to create a flow path for fluid 102 through header assembly 112. Vehicle connector 136 extends from header housing 134 to create an electrical connection with vehicle 106 to vehicle system 108.

In an exemplary embodiment, header assembly 112 includes fluid pump 150 for circulating fluid through header assembly 112. For example, the fluid pump 150 can be connected to the suction line fitting 130 to pump fluid through the system. The fluid pump 150 is used to control the pressure of the fluid within the closed sample loop for consistent sampling by the fluid sensor assembly 100. The fluid pump 150 can maintain a constant pressure within the sample loop so that sampling occurs at a constant pressure. The fluid pump 150 is used to drain fluid from the fluid tank 104 into the header assembly 112. The fluid 102 in the sample loop may be free of air bubbles, which may improve the test quality of the fluid 102. For example, the fluid pump 150 can pressurize the fluid to remove any air bubbles in the sample loop.

Header assembly 112 includes a sample tank 152 in fluid communication with suction line fitting 130 and return line fitting 132. In the exemplary embodiment, the sample tank 152 is in the header housing 134. Alternatively, the sample tank 152 can be located away from the header housing 134 outside the fluid tank 104. The fluid 102 is circulated from the sample suction line 122 through the sample tank 152 by the fluid pump 150 to the sample return line 124. In an exemplary embodiment, fluid is tested in sample tank 152. As such, sampling of the fluid 102 occurs outside the fluid tank 104, such as within the header housing 134 of the header assembly 112. Sample tank 152 may be a small, controlled environment for testing fluids. For example, because the sample tank is away from the fluid tank 104, the temperature can generally be controlled within the sample tank 152 regardless of the temperature of the fluid in the fluid tank 104. Since the sample tank is away from the fluid tank 104, the sample tank can generally control the pressure regulation in the sample tank 152 regardless of the pressure of the fluid in the fluid tank 104.

In an exemplary embodiment, header assembly 112 includes a fluid quality sensor 154 in header housing 134. The fluid quality sensor 154 tests the fluid 102 within the sample tank 152. The fluid quality sensor 154 can detect one or more fluid properties of the fluid 102. For example, fluid quality sensor 154 can detect the concentration of one or more substances in fluid 102. The fluid quality sensor 154 can detect contamination of the fluid 102. The fluid quality sensor 154 can detect other fluid properties such as temperature, viscosity, density, and the like. In an exemplary embodiment, fluid quality sensor 154 includes ultrasonic transducer 156 for quality sampling of fluid 102. Other types of sampling sensors can be provided in various other embodiments. The ultrasonic transducer 156 can be located in or within the sample tank 152 for quality testing of the fluid 102. The ultrasonic transducer 156 transmits an ultrasonic signal through the fluid 102 to test one or more quality characteristics of the fluid. In various other embodiments, the fluid quality sensor 154 can include other types of sensing elements. For example, the fluid quality sensor 154 can include an infrared sensor configured to transmit an infrared signal through the fluid in the sample tank 152. Optionally, the fluid quality sensor 154 can include other types of sensors to sense different quality characteristics of the fluid.

In an exemplary embodiment, header assembly 112 includes sensor circuit board 160 having one or more sensor components 162 on sensor circuit board 160. The sensor component 162 can be used for data processing of signals from the fluid quality sensor 154 to determine one or more quality characteristics of the fluid 102. The sensor component 162 may include one or more processors, memory, communication components, and the like. The fluid quality sensor 154 is electrically connected to the sensor circuit board 160 by, for example, a wire or a connector. The operation of the fluid quality sensor 154 can be controlled by one or more sensor components 162 on the sensor circuit board 160. Data from the fluid quality sensor 154 can be analyzed by one or more sensor components 162 on the sensor circuit board 160. Data from the fluid quality sensor 154 can be transmitted by one or more sensor components 162 to other components, such as the vehicle connector 136 and/or the vehicle system 108.

In an exemplary embodiment, sensor connector 140 is electrically connected to sensor circuit board 160. Data from the fluid level sensor assembly 114 can be transmitted through the sensor connector 140 to one or more sensor components 162 on the sensor circuit board 160. Data from the fluid level sensor assembly 114 can be transmitted by one or more sensor components 162 to other components, such as the vehicle connector 136 and/or the vehicle system 108.

In an exemplary embodiment, the header assembly 112 includes a heating element circuit board 170 for controlling the operation of the heating element 172 of the temperature control device 116. The heating element circuit board 170 can be electrically connected to the vehicle connector 136, for example, to receive power from the vehicle.

3 is an exploded view of a fluid sensor assembly 100 according to an exemplary embodiment. 3 shows a temperature control device 116 comprising a heating element 172. Heating element 172 includes heating element connector 174 configured to be electrically connected to header assembly 112. 3 shows the sample suction line 122 and the sample return line 124 extending from the bottom of the base plate 120. In an exemplary embodiment, a filter 180 is provided on the sample aspiration line 122 to filter the fluid 102 circulated through the closed sample loop. 3 shows the suction line fitting 126 and return line fitting 128 at the top of the base plate 120 for interfacing with the header assembly 112.

In an exemplary embodiment, the header assembly 112 is provided separately from the housing unit 110 and is configured to be removably connected to the housing unit 110. The suction line fitting 130 and the return line fitting 132 may be matched with the suction line fitting 126 and the return line fitting 128, respectively. The header assembly 112 includes a heating element connector 176 configured to mate with the heating element connector 174 of the temperature control device 116, for example to power the temperature control device 116. . The header assembly 112 includes a sensor connector 140 configured to connect to the fluid level sensor connector 182 of the fluid level sensor assembly 114. The header assembly 112 is removably connected to the housing unit 110 so that the header assembly 112 can be replaced, for example, if one or more components of the header assembly 112 are defective or require an upgrade. . The header assembly 112 can be removed and replaced in the field without removing and/or replacing the housing unit 110.

In an exemplary embodiment, the fluid level sensor assembly 114 is provided separately from the housing unit 110 and is configured to be removably connected to the housing unit 110. The fluid level sensor connector 182 may be removably connected to the sensor connector 140. For example, the fluid level sensor assembly 114 can be connected to the base plate 120 and/or extended through the base plate 120 to interface with the header assembly 112.

4 is an exploded view of a fluid sensor assembly 100 according to an exemplary embodiment. 4 shows a temperature control device 116 that includes a cooling element 192. The cooling element 192 includes a coolant line 194 having a supply fitting 196 and return fitting 198. The coolant is circulated through the coolant line 194. Coolant line 194 is configured to thermally communicate with fluid 102 in fluid tank 104 to heat fluid 102, for example, to prevent freezing of fluid 102. Optionally, a heating element can be provided to heat the fluid.

Claims (10)

A fluid sensor assembly (100) for sensing fluid (102) contained within a fluid tank (104) of a vehicle (106),
A housing unit 110 having a base plate 120 configured to be connected to the fluid tank, and including a sample suction line 122 and a sample return line 124 configured to be in fluid communication with the fluid in the fluid tank; And
Has a header housing (134) detachably connected to the housing unit and configured to be located outside the fluid tank of the vehicle, in fluid communication with the sample suction line and the sample return line and receiving fluid from the fluid tank A header assembly comprising a fluid quality sensor 154 that has a sample tank 152 configured to sense the quality characteristics of the fluid in the sample tank for sampling the quality of the fluid at a location away from the interior of the fluid tank 102) a fluid sensor assembly (100). According to claim 1,
The header assembly 102 is a fluid sensor assembly 100 detachable from the housing unit 110 without removing the housing unit from the fluid tank 104. According to claim 1,
The header assembly 102 is a sealed fluid sensor assembly 100. According to claim 1,
The sample tank 152 is a fluid sensor assembly 100 contained within the header housing 134. According to claim 1,
The housing unit 110 includes a suction line fitting 126 and a return line fitting 128, wherein the header assembly 102 is a suction line fitting 130 removably connected to the suction line fitting of the housing unit And a return line fitting 132 removably connected to the return line fitting of the housing unit. According to claim 1,
The sample suction line 122 and the sample return line 124 are fluid sensor assemblies 100 forming a closed sample loop for sampling the fluid 102. According to claim 1,
The header assembly 102 is a fluid sensor assembly 100 comprising a vehicular connector 136 configured to be connected to an electrical connector 138 of the vehicle 106. According to claim 1,
The header assembly 102 is a fluid sensor assembly 100 comprising a pump 150 in flow communication with the sample suction line 122. According to claim 1,
The header assembly 102 includes a sensor circuit board 160, wherein the sensor circuit board is a fluid sensor assembly 100 that is electrically connected to the fluid quality sensor 154. According to claim 1,
The fluid quality sensor 154 is a fluid sensor assembly 100 that includes an ultrasonic transducer 156 in the sample tank 152 for quality sampling of the fluid 102.

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